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Commit 7edad61c authored by pekka@orca.ndb.mysql.com's avatar pekka@orca.ndb.mysql.com
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ndb - bug#21191: test pgm: testIndexStat

parent 94e17bd6
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storage/ndb/test/ndbapi/Makefile.am
View file @ 7edad61c
......@@ -36,7 +36,8 @@ testPartitioning \
testBitfield \
DbCreate DbAsyncGenerator \
testSRBank \
test_event_merge
test_event_merge \
testIndexStat
EXTRA_PROGRAMS = \
test_event \
......@@ -87,6 +88,7 @@ DbAsyncGenerator_SOURCES = bench/mainAsyncGenerator.cpp bench/asyncGenerator.cpp
testSRBank_SOURCES = testSRBank.cpp
test_event_merge_SOURCES = test_event_merge.cpp
test_event_multi_table_SOURCES = test_event_multi_table.cpp
testIndexStat_SOURCES = testIndexStat.cpp
INCLUDES_LOC = -I$(top_srcdir)/storage/ndb/include/kernel
......@@ -168,3 +170,4 @@ testScan.dsp: Makefile \
@$(top_srcdir)/storage/ndb/config/win-sources $@ $(testScan_SOURCES)
@$(top_srcdir)/storage/ndb/config/win-libraries $@ LINK $(LDADD)
storage/ndb/test/ndbapi/testIndexStat.cpp 0 → 100644
View file @ 7edad61c
/* Copyright (C) 2005 MySQL AB
This program is free software; you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation; either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */
#include <ndb_global.h>
#include <ndb_opts.h>
#include <NdbApi.hpp>
#include <NdbIndexStat.hpp>
#include <NdbTest.hpp>
#include <my_sys.h>
#include <ndb_version.h>
#include <math.h>
/*
* Sample results:
*
* 0. err pct: count: 1000 min: -99.99 max: 99.92 avg: 6.88 stddev: 27.61
*
* 0. baseline with same options as handler
*/
#undef min
#undef max
#define min(a, b) ((a) <= (b) ? (a) : (b))
#define max(a, b) ((a) >= (b) ? (a) : (b))
inline NdbOut&
NdbOut::operator<<(double x)
{
char buf[100];
sprintf(buf, "%.2f", x);
*this << buf;
return *this;
}
struct Opts {
int loglevel;
uint seed;
uint loop;
uint rows;
uint ops;
uint nullkeys;
uint dupkeys;
uint scanpct;
uint eqscans;
uint dupscans;
my_bool keeptable;
my_bool loaddata;
my_bool nochecks;
my_bool abort;
// internal
uint tryhard;
Opts() :
loglevel(0),
seed(-1),
loop(1),
rows(100000),
ops(1000),
nullkeys(10),
dupkeys(1000),
scanpct(5),
eqscans(50),
dupscans(10),
keeptable(false),
loaddata(true),
nochecks(false),
abort(false),
// internal
tryhard(20)
{}
};
static Opts g_opts;
const char* g_progname = "testIndexStat";
static uint g_loop = 0;
static const char* g_tabname = "ts0";
static const char* g_indname = "ts0x1";
static const char g_numattrs = 3;
static const uint g_charlen = 10;
static const char* g_csname = "latin1_swedish_ci";
static CHARSET_INFO* g_cs;
// value and bound ranges
static uint g_val_b_max = 10;
static uint g_bnd_b_max = 20;
static const char* g_val_c_char = "bcd";
static const char* g_bnd_c_char = "abcde";
static uint g_val_d_max = 100;
static uint g_bnd_d_max = 200;
static Ndb_cluster_connection* g_ncc = 0;
static Ndb* g_ndb = 0;
static NdbDictionary::Dictionary* g_dic = 0;
static const NdbDictionary::Table* g_tab = 0;
static const NdbDictionary::Index* g_ind = 0;
static NdbIndexStat* g_stat = 0;
static NdbTransaction* g_con = 0;
static NdbOperation* g_op = 0;
static NdbScanOperation* g_scan_op = 0;
static NdbIndexScanOperation* g_rangescan_op = 0;
static uint
urandom()
{
uint r = (uint)random();
return r;
}
static uint
urandom(uint m)
{
if (m == 0)
return 0;
uint r = urandom();
r = r % m;
return r;
}
static int& g_loglevel = g_opts.loglevel; // default log level
#define chkdb(x) \
do { if (likely(x)) break; ndbout << "line " << __LINE__ << " FAIL " << #x << endl; errdb(); if (g_opts.abort) abort(); return -1; } while (0)
#define chkrc(x) \
do { if (likely(x)) break; ndbout << "line " << __LINE__ << " FAIL " << #x << endl; if (g_opts.abort) abort(); return -1; } while (0)
#define reqrc(x) \
do { if (likely(x)) break; ndbout << "line " << __LINE__ << " ASSERT " << #x << endl; abort(); } while (0)
#define llx(n, x) \
do { if (likely(g_loglevel < n)) break; ndbout << x << endl; } while (0)
#define ll0(x) llx(0, x)
#define ll1(x) llx(1, x)
#define ll2(x) llx(2, x)
#define ll3(x) llx(3, x)
static void
errdb()
{
uint any = 0;
// g_ncc return no error...
if (g_ndb != 0) {
const NdbError& e = g_ndb->getNdbError();
if (e.code != 0)
ll0(++any << " ndb: error " << e);
}
if (g_dic != 0) {
const NdbError& e = g_dic->getNdbError();
if (e.code != 0)
ll0(++any << " dic: error " << e);
}
if (g_con != 0) {
const NdbError& e = g_con->getNdbError();
if (e.code != 0)
ll0(++any << " con: error " << e);
}
if (g_op != 0) {
const NdbError& e = g_op->getNdbError();
if (e.code != 0)
ll0(++any << " op: error " << e);
}
if (g_scan_op != 0) {
const NdbError& e = g_scan_op->getNdbError();
if (e.code != 0)
ll0(++any << " scan_op: error " << e);
}
if (g_rangescan_op != 0) {
const NdbError& e = g_rangescan_op->getNdbError();
if (e.code != 0)
ll0(++any << " rangescan_op: error " << e);
}
if (g_stat != 0) {
const NdbError& e = g_stat->getNdbError();
if (e.code != 0)
ll0(++any << " stat: error " << e);
}
if (! any)
ll0("unknown db error");
}
// create table ts0 (
// a int unsigned, b smallint not null, c varchar(10), d int unsigned,
// primary key using hash (a), index (b, c, d) )
static int
createtable()
{
NdbDictionary::Table tab(g_tabname);
tab.setLogging(false);
{
NdbDictionary::Column col("a");
col.setType(NdbDictionary::Column::Unsigned);
col.setPrimaryKey(true);
tab.addColumn(col);
}
{
NdbDictionary::Column col("b");
col.setType(NdbDictionary::Column::Smallint);
col.setNullable(false);
tab.addColumn(col);
}
{
NdbDictionary::Column col("c");
col.setType(NdbDictionary::Column::Varchar);
col.setLength(g_charlen);
col.setCharset(g_cs);
col.setNullable(true);
tab.addColumn(col);
}
{
NdbDictionary::Column col("d");
col.setType(NdbDictionary::Column::Unsigned);
col.setNullable(true);
tab.addColumn(col);
}
NdbDictionary::Index ind(g_indname);
ind.setTable(g_tabname);
ind.setType(NdbDictionary::Index::OrderedIndex);
ind.setLogging(false);
ind.addColumnName("b");
ind.addColumnName("c");
ind.addColumnName("d");
g_dic = g_ndb->getDictionary();
if (! g_opts.keeptable) {
if (g_dic->getTable(g_tabname) != 0)
chkdb(g_dic->dropTable(g_tabname) == 0);
chkdb(g_dic->createTable(tab) == 0);
chkdb(g_dic->createIndex(ind) == 0);
} else {
if (g_dic->getTable(g_tabname) == 0) {
chkdb(g_dic->createTable(tab) == 0);
chkdb(g_dic->createIndex(ind) == 0);
} else
g_opts.loaddata = false;
}
chkdb((g_tab = g_dic->getTable(g_tabname)) != 0);
chkdb((g_ind = g_dic->getIndex(g_indname, g_tabname)) != 0);
g_dic = 0;
return 0;
}
static int
droptable()
{
g_dic = g_ndb->getDictionary();
if (! g_opts.keeptable)
chkdb(g_dic->dropTable(g_tabname) == 0);
g_dic = 0;
return 0;
}
struct Val {
Int16 b;
bool c_null;
uchar c[1 + g_charlen];
bool d_null;
Uint32 d;
// partial values for use in Bnd
uint numattrs;
void make(uint n = g_numattrs, bool is_val = true);
int cmp(const Val& val, uint n = g_numattrs) const;
};
static NdbOut&
operator<<(NdbOut& out, const Val& val)
{
out << "[";
if (val.numattrs >= 1) {
out << val.b;
}
if (val.numattrs >= 2) {
out << " ";
if (val.c_null)
out << "NULL";
else {
char buf[1 + g_charlen];
sprintf(buf, "%.*s", val.c[0], &val.c[1]);
out << "'" << buf << "'";
}
}
if (val.numattrs >= 3) {
out << " ";
if (val.d_null)
out <<" NULL";
else
out << val.d;
}
out << "]";
return out;
}
void
Val::make(uint n, bool is_val)
{
if (n >= 1) {
uint b_max = is_val ? g_val_b_max : g_bnd_b_max;
b = (int)urandom(2 * b_max) - (int)b_max;
}
if (n >= 2) {
if (urandom(100) < g_opts.nullkeys)
c_null = 1;
else {
const char* c_char = is_val ? g_val_c_char : g_bnd_c_char;
// prefer shorter
uint len = urandom(urandom(g_charlen + 2));
c[0] = len;
uint j;
for (j = 0; j < len; j++) {
uint k = urandom(strlen(c_char));
c[1 + j] = c_char[k];
}
c_null = 0;
}
}
if (n >= 3) {
if (urandom(100) < g_opts.nullkeys)
d_null = 1;
else {
uint d_max = is_val ? g_val_d_max : g_bnd_d_max;
d = urandom(d_max);
d_null = 0;
}
}
numattrs = n;
}
int
Val::cmp(const Val& val, uint n) const
{
int k = 0;
if (k == 0 && n >= 1) {
if (b < val.b)
k = -1;
else if (b > val.b)
k = +1;
}
if (k == 0 && n >= 2) {
if (! c_null && ! val.c_null) {
const uchar* s1 = &c[1];
const uchar* s2 = &val.c[1];
const uint l1 = (uint)c[0];
const uint l2 = (uint)val.c[0];
assert(l1 <= g_charlen && l2 <= g_charlen);
k = g_cs->coll->strnncollsp(g_cs, s1, l1, s2, l2, 0);
} else if (! c_null) {
k = +1;
} else if (! val.c_null) {
k = -1;
}
}
if (k == 0 && n >= 3) {
if (! d_null && ! val.d_null) {
if (d < val.d)
k = -1;
else if (d > val.d)
k = +1;
} else if (! d_null) {
k = +1;
} else if (! val.d_null) {
k = -1;
}
}
return k;
}
struct Key {
Val val;
union {
bool flag;
uint count;
uint rpk;
};
};
static NdbOut&
operator<<(NdbOut& out, const Key& key)
{
out << key.val << " info:" << key.count;
return out;
}
static Key* g_keys = 0;
static Key* g_sortkeys = 0;
static uint g_sortcount = 0;
static Key* g_minkey = 0;
static Key* g_maxkey = 0;
static void
freekeys()
{
if (g_keys != 0)
my_free((char*)g_keys, MYF(0));
if (g_sortkeys != 0)
my_free((char*)g_sortkeys, MYF(0));
g_keys = 0;
g_sortkeys = 0;
}
static int
allockeys()
{
freekeys();
size_t sz = sizeof(Key) * g_opts.rows;
g_keys = (Key*)my_malloc(sz, MYF(0));
g_sortkeys = (Key*)my_malloc(sz, MYF(0));
chkrc(g_keys != 0 && g_sortkeys != 0);
memset(g_keys, 0x1f, sz);
memset(g_sortkeys, 0x1f, sz);
return 0;
}
static void
makekeys()
{
uint i;
for (i = 0; i < g_opts.rows; i++) {
Key& key = g_keys[i];
key.val.make();
key.flag = false; // mark for dup generation done
}
for (i = 0; i < g_opts.rows; i++) {
Key& key = g_keys[i];
if (key.flag)
continue;
key.flag = true;
uint fudge = 9;
uint n = (urandom(fudge * (g_opts.dupkeys - 100)) + 99) / 100;
uint k;
for (k = 1; k < n; k++) {
uint j = urandom(g_opts.rows);
do {
Key& dst = g_keys[j];
if (! dst.flag) {
dst.val = key.val;
dst.flag = true;
break;
}
} while (urandom(g_opts.tryhard) != 0);
}
}
}
static int
insertdata()
{
const uint batch = 512;
chkdb((g_con = g_ndb->startTransaction()) != 0);
uint i = 0;
while (i < g_opts.rows) {
chkdb((g_op = g_con->getNdbOperation(g_tab)) != 0);
chkdb(g_op->insertTuple() == 0);
Uint32 a = i;
const Val& val = g_keys[i].val;
const char* a_addr = (const char*)&a;
const char* b_addr = (const char*)&val.b;
const char* c_addr = ! val.c_null ? (const char*)val.c : 0;
const char* d_addr = ! val.d_null ? (const char*)&val.d : 0;
Uint32 no = 0;
chkdb(g_op->equal(no++, a_addr) == 0);
chkdb(g_op->setValue(no++, b_addr) == 0);
chkdb(g_op->setValue(no++, c_addr) == 0);
chkdb(g_op->setValue(no++, d_addr) == 0);
if (i++ % batch == 0) {
chkdb(g_con->execute(NdbTransaction::Commit) == 0);
g_ndb->closeTransaction(g_con);
g_con = 0;
g_op = 0;
chkdb((g_con = g_ndb->startTransaction()) != 0);
}
}
chkdb(g_con->execute(NdbTransaction::Commit) == 0);
g_ndb->closeTransaction(g_con);
g_con = 0;
g_op = 0;
ll0(g_tabname << ": inserted " << g_opts.rows << " rows");
return 0;
}
static int
countrows()
{
Uint64 rows = 0;
Uint64 r;
char* r_addr = (char*)&r;
chkdb((g_con = g_ndb->startTransaction()) != 0);
chkdb((g_scan_op = g_con->getNdbScanOperation(g_tab)) != 0);
chkdb(g_scan_op->readTuples() == 0);
chkdb(g_scan_op->interpret_exit_last_row() == 0);
chkdb(g_scan_op->getValue(NdbDictionary::Column::ROW_COUNT, r_addr) != 0);
chkdb(g_con->execute(NdbTransaction::NoCommit) == 0);
while (1) {
int ret;
r = ~(Uint64)0;
chkdb((ret = g_scan_op->nextResult()) == 0 || ret == 1);
if (ret == 1)
break;
rows += r;
}
g_ndb->closeTransaction(g_con);
g_con = 0;
g_scan_op = 0;
g_opts.rows = rows;
return 0;
}
static int
scandata()
{
chkdb((g_con = g_ndb->startTransaction()) != 0);
chkdb((g_scan_op = g_con->getNdbScanOperation(g_tab)) != 0);
chkdb(g_scan_op->readTuples() == 0);
Uint32 a;
Val val;
char* a_addr = (char*)&a;
char* b_addr = (char*)&val.b;
char* c_addr = (char*)val.c;
char* d_addr = (char*)&val.d;
Uint32 no = 0;
NdbRecAttr* b_ra;
NdbRecAttr* c_ra;
NdbRecAttr* d_ra;
chkdb(g_scan_op->getValue(no++, a_addr) != 0);
chkdb((b_ra = g_scan_op->getValue(no++, b_addr)) != 0);
chkdb((c_ra = g_scan_op->getValue(no++, c_addr)) != 0);
chkdb((d_ra = g_scan_op->getValue(no++, d_addr)) != 0);
chkdb(g_con->execute(NdbTransaction::NoCommit) == 0);
uint count = 0;
uint i;
for (i = 0; i < g_opts.rows; i++)
g_keys[i].count = 0;
while (1) {
int ret;
a = ~(Uint32)0;
chkdb((ret = g_scan_op->nextResult()) == 0 || ret == 1);
if (ret == 1)
break;
assert(b_ra->isNULL() == 0 && c_ra->isNULL() != -1 && d_ra->isNULL() != -1);
val.c_null = c_ra->isNULL();
val.d_null = d_ra->isNULL();
i = (uint)a;
chkrc(i < g_opts.rows);
Key& key = g_keys[i];
if (g_opts.loaddata)
chkrc(key.val.cmp(val) == 0);
else
key.val = val;
key.count++;
count++;
}
g_ndb->closeTransaction(g_con);
g_con = 0;
g_scan_op = 0;
for (i = 0; i < g_opts.rows; i++)
chkrc(g_keys[i].count == 1);
assert(count == g_opts.rows);
int level = g_opts.loaddata ? 1 : 0;
llx(level, g_tabname << ": scanned " << g_opts.rows << " rows");
return 0;
}
static int
loaddata()
{
if (g_opts.loaddata) {
chkrc(allockeys() == 0);
makekeys();
chkrc(insertdata() == 0);
} else {
chkrc(countrows() == 0);
chkrc(g_opts.rows != 0);
ll0(g_tabname << ": using old table of " << g_opts.rows << " rows");
chkrc(allockeys() == 0);
}
chkrc(scandata() == 0);
uint i;
for (i = 0; i < g_opts.rows; i++)
ll3(i << ": " << g_keys[i]);
return 0;
}
// true = match, index = match or next higher
static bool
sortval(const Val& val, int& index)
{
if (unlikely(g_sortcount == 0)) {
index = 0;
return false;
}
int lo = -1;
int hi = (int)g_sortcount;
int ret;
int j;
do {
j = (hi + lo) / 2;
ret = val.cmp(g_sortkeys[j].val);
if (ret < 0)
hi = j;
else if (ret > 0)
lo = j;
else
break;
} while (hi - lo > 1);
if (ret == 0) {
index = j;
return true;
}
index = hi;
return false;
}
static void
sortkeys()
{
// insert sort with binary search
g_sortcount = 0;
uint i;
for (i = 0; i < g_opts.rows; i++) {
const Val& val = g_keys[i].val;
int index;
bool match = sortval(val, index);
Key& dst = g_sortkeys[index];
if (match) {
dst.rpk++;
} else {
uint bytes = ((int)g_sortcount - index) * sizeof(Key);
memmove(&dst + 1, &dst, bytes);
dst.val = val;
dst.rpk = 1;
g_sortcount++;
}
}
g_minkey = &g_sortkeys[0];
g_maxkey = &g_sortkeys[g_sortcount - 1];
ll1("counted " << g_sortcount << " distinct keys");
}
struct Bnd {
Val val;
/*
* A bound is a partial key value (0 to g_numattrs attributes).
* It is not equal to any key value. Instead, it has a "side".
*
* side = 0 if the bound is empty
* side = -1 if the bound is "just before" its value
* side = +1 if the bound is "just after" its value
*
* This is another way of looking at strictness of non-empty
* start and end keys in a range.
*
* start key is strict if side = +1
* end key is strict if side = -1
*
* NDB API specifies strictness in the bound type of the last
* index attribute which is part of the start/end key.
*
* LE (0) - strict: n - side: -1
* LT (1) - strict: y - side: +1
* GE (2) - strict: n - side: +1
* GT (3) - strict: y - side: -1
*
* A non-empty bound divides keys into 2 disjoint subsets:
* keys before (cmp() == -1) and keys after (cmp() == +1).
*/
int side;
Bnd& make(uint minattrs);
Bnd& make(uint minattrs, const Val& theval);
int cmp(const Val& val) const;
int type(uint lohi, uint colno) const; // for setBound
};
static NdbOut&
operator<<(NdbOut& out, const Bnd& bnd)
{
out << bnd.val;
out << " side: " << bnd.side;
return out;
}
Bnd&
Bnd::make(uint minattrs)
{
uint numattrs = minattrs + urandom(g_numattrs - minattrs);
val.make(numattrs, false);
side = val.numattrs == 0 ? 0 : urandom(2) == 0 ? -1 : +1;
return *this;
}
Bnd&
Bnd::make(uint minattrs, const Val& theval)
{
uint numattrs = minattrs + urandom(g_numattrs - minattrs);
val = theval;
val.numattrs = numattrs;
side = val.numattrs == 0 ? 0 : urandom(2) == 0 ? -1 : +1;
return *this;
}
int
Bnd::cmp(const Val& theval) const
{
int place; // debug
int ret;
do {
assert(theval.numattrs == g_numattrs);
int k = theval.cmp(val, val.numattrs);
if (k != 0) {
place = 1;
ret = k;
break;
}
if (side != 0) {
place = 2;
ret = -side;
break;
}
place = 3;
ret = 0;
assert(val.numattrs == 0);
} while (0);
ll3("cmp: val: " << theval << " bnd: " << *this <<
" return: " << ret << " at " << place);
return ret;
}
int
Bnd::type(uint lohi, uint colno) const
{
int t;
assert(lohi <= 1 && colno < val.numattrs && (side == -1 || side == +1));
if (lohi == 0) {
if (colno + 1 < val.numattrs)
t = 0; // LE
else if (side == -1)
t = 0; // LE
else
t = 1; // LT
} else {
if (colno + 1 < val.numattrs)
t = 2; // GE
else if (side == +1)
t = 2; // GE
else
t = 3; // GT
}
return t;
}
struct Range {
Bnd bnd[2];
uint minattrs() const;
uint maxattrs() const;
int cmp(const Val& val) const; // -1,0,+1 = key is before,in,after range
uint rowcount() const;
bool iseq() const;
// stats
bool flag;
uint statrows;
uint scanrows;
double errpct;
};
static NdbOut&
operator<<(NdbOut& out, const Range& range)
{
out << "bnd0: " << range.bnd[0] << " bnd1: " << range.bnd[1];
return out;
}
uint
Range::minattrs() const
{
return min(bnd[0].val.numattrs, bnd[1].val.numattrs);
}
uint
Range::maxattrs() const
{
return max(bnd[0].val.numattrs, bnd[1].val.numattrs);
}
int
Range::cmp(const Val& theval) const
{
int place; // debug
int ret;
do {
int k;
k = bnd[0].cmp(theval);
if (k < 0) {
place = 1;
ret = -1;
break;
}
k = bnd[1].cmp(theval);
if (k > 0) {
place = 2;
ret = +1;
break;
}
place = 3;
ret = 0;
} while (0);
ll3("cmp: val: " << theval << " range: " << *this <<
" return: " << ret << " at " << place);
return ret;
}
uint
Range::rowcount() const
{
ll2("rowcount: " << *this);
int i;
// binary search for first and last in range
int lim[2];
for (i = 0; i <= 1; i++) {
ll3("search i=" << i);
int lo = -1;
int hi = (int)g_sortcount;
int ret;
int j;
do {
j = (hi + lo) / 2;
ret = cmp(g_sortkeys[j].val);
if (i == 0) {
if (ret < 0)
lo = j;
else
hi = j;
} else {
if (ret > 0)
hi = j;
else
lo = j;
}
} while (hi - lo > 1);
if (ret == 0)
lim[i] = j;
else if (i == 0)
lim[i] = hi;
else
lim[i] = lo;
}
// the range
const int lo = max(lim[0], 0);
const int hi = min(lim[1], (int)g_sortcount - 1);
if (! g_opts.nochecks) {
int curr = -1;
for (i = 0; i < (int)g_sortcount; i++) {
int k = cmp(g_sortkeys[i].val);
if (k < 0)
assert(i < lo);
else if (k == 0)
assert(lo <= i && i <= hi);
else
assert(i > hi);
assert(curr <= k);
if (curr < k)
curr = k;
}
}
// sum them up
uint count = 0;
for (i = lo; i <= hi; i++)
count += g_sortkeys[i].count;
ll2("count: " << count << " index lim: " << lim[0] << " " << lim[1]);
return count;
}
bool
Range::iseq() const
{
return
minattrs() == maxattrs() &&
bnd[0].val.cmp(bnd[1].val, minattrs()) == 0 &&
bnd[0].side < bnd[1].side;
}
static Range* g_ranges = 0;
static void
freeranges()
{
if (g_ranges != 0)
my_free((char*)g_ranges, MYF(0));
g_ranges = 0;
}
static int
allocranges()
{
freeranges();
size_t sz = sizeof(Range) * g_opts.ops;
g_ranges = (Range*)my_malloc(sz, MYF(0));
chkrc(g_ranges != 0);
memset(g_ranges, 0x1f, sz);
return 0;
}
static void
makeranges()
{
uint i;
for (i = 0; i < g_opts.ops; i++) {
Range& range = g_ranges[i];
range.flag = false; // mark for dup generation done
bool fulleq = (urandom(100) < g_opts.eqscans);
bool eq = fulleq || (urandom(100) < g_opts.eqscans);
bool matcheq = eq && (urandom(10) != 0);
if (! eq) {
// random but prefer non-empty and no more than scanpct
do {
range.bnd[0].make(0);
range.bnd[1].make(0);
uint count = range.rowcount();
if (count != 0 && 100 * count <= g_opts.scanpct * g_opts.rows)
break;
} while (urandom(g_opts.tryhard) != 0);
} else {
uint minattrs = fulleq ? g_numattrs : 1;
if (! matcheq) {
range.bnd[0].make(minattrs);
} else {
uint m = urandom(g_sortcount);
const Val& val = g_sortkeys[m].val;
range.bnd[0].make(minattrs, val);
}
range.bnd[1] = range.bnd[0];
range.bnd[0].side = -1;
range.bnd[1].side = +1;
// fix types
range.bnd[0];
range.bnd[1];
assert(range.iseq());
}
}
for (i = 0; i < g_opts.ops; i++) {
Range& range = g_ranges[i];
if (range.flag)
continue;
range.flag = true;
if (urandom(100) < g_opts.dupscans) {
uint j = urandom(g_opts.ops);
do {
Range& dst = g_ranges[j];
if (! dst.flag) {
dst.bnd[0] = range.bnd[0];
dst.bnd[1] = range.bnd[1];
dst.flag = true;
break;
}
} while (urandom(g_opts.tryhard) != 0);
}
}
}
static int
setbounds(const Range& range)
{
// currently must do each attr in order
ll2("setbounds: " << range);
uint i;
const Bnd (&bnd)[2] = range.bnd;
for (i = 0; i < g_numattrs; i++) {
const Uint32 no = i; // index attribute number
uint j;
int type[2] = { -1, -1 };
for (j = 0; j <= 1; j++) {
if (no < bnd[j].val.numattrs)
type[j] = bnd[j].type(j, no);
}
for (j = 0; j <= 1; j++) {
int t = type[j];
if (t == -1)
continue;
if (no + 1 < bnd[j].val.numattrs)
t &= ~(uint)1; // strict bit is set on last bound only
const Val& val = bnd[j].val;
const void* addr = 0;
if (no == 0)
addr = (const void*)&val.b;
else if (no == 1)
addr = ! val.c_null ? (const void*)val.c : 0;
else if (no == 2)
addr = ! val.d_null ? (const void*)&val.d : 0;
else
assert(false);
ll2("setBound attr:" << no << " type:" << t << " val: " << val);
chkdb(g_rangescan_op->setBound(no, t, addr) == 0);
}
}
return 0;
}
static int
allocstat()
{
g_stat = new NdbIndexStat(g_ind);
chkdb(g_stat->alloc_cache(32) == 0);
return 0;
}
static int
runstat(Range& range, int flags)
{
ll2("runstat: " << range << " flags=" << flags);
chkdb((g_con = g_ndb->startTransaction()) != 0);
chkdb((g_rangescan_op = g_con->getNdbIndexScanOperation(g_ind, g_tab)) != 0);
chkdb(g_rangescan_op->readTuples(NdbOperation::LM_CommittedRead) == 0);
chkrc(setbounds(range) == 0);
Uint64 count = ~(Uint64)0;
chkdb(g_stat->records_in_range(g_ind, g_rangescan_op, g_opts.rows, &count, flags) == 0);
g_ndb->closeTransaction(g_con);
g_con = 0;
g_rangescan_op = 0;
range.statrows = (uint)count;
chkrc((Uint64)range.statrows == count);
ll2("stat: " << range.statrows);
return 0;
}
static int
runscan(Range& range)
{
ll2("runscan: " << range);
chkdb((g_con = g_ndb->startTransaction()) != 0);
chkdb((g_rangescan_op = g_con->getNdbIndexScanOperation(g_ind, g_tab)) != 0);
chkdb(g_rangescan_op->readTuples() == 0);
chkrc(setbounds(range) == 0);
Uint32 a;
char* a_addr = (char*)&a;
Uint32 no = 0;
chkdb(g_rangescan_op->getValue(no++, a_addr) != 0);
chkdb(g_con->execute(NdbTransaction::NoCommit) == 0);
uint count = 0;
uint i;
for (i = 0; i < g_opts.rows; i++)
g_keys[i].count = 0;
while (1) {
int ret;
a = ~(Uint32)0;
chkdb((ret = g_rangescan_op->nextResult()) == 0 || ret == 1);
if (ret == 1)
break;
i = (uint)a;
chkrc(i < g_opts.rows);
Key& key = g_keys[i];
ll3("scan: " << key);
int k = range.cmp(key.val);
chkrc(k == 0);
chkrc(key.count == 0);
key.count++;
count++;
}
g_ndb->closeTransaction(g_con);
g_con = 0;
g_rangescan_op = 0;
if (! g_opts.nochecks) {
for (i = 0; i < g_opts.rows; i++) {
const Key& key = g_keys[i];
int k = range.cmp(key.val);
assert((k != 0 && key.count == 0) || (k == 0 && key.count == 1));
}
assert(range.rowcount() == count);
}
range.scanrows = count;
ll2("scan: " << range.scanrows);
return 0;
}
static int
runscans()
{
uint i;
for (i = 0; i < g_opts.ops; i++) {
Range& range = g_ranges[i];
ll1("range " << i << ": " << range);
// simulate old handler code
int flags = 0;
if (i < 32 || i % 20 == 0)
flags |= NdbIndexStat::RR_UseDb;
chkrc(runstat(range, flags) == 0);
chkrc(runscan(range) == 0);
// if stat is 0 then it is exact scan count
chkrc(range.statrows != 0 || range.scanrows == 0);
// measure error as fraction of total rows
double x = (double)range.statrows;
double y = (double)range.scanrows;
double z = (double)g_opts.rows;
double err = (x - y) / z;
// report in pct
range.errpct = 100.0 * err;
ll1("range " << i << ":" <<
" stat: " << range.statrows << " scan: " << range.scanrows <<
" errpct: " << range.errpct);
}
return 0;
}
struct Stat {
const char* name;
uint count;
double sum;
double minval;
double maxval;
double avg;
double varsum;
double var;
double stddev;
void init();
void add(const Stat& stat);
};
void
Stat::init()
{
name = "stat";
count = 0;
sum = minval = maxval = avg = varsum = var = stddev = 0.0;
}
void
Stat::add(const Stat& stat)
{
if (count == 0) {
*this = stat;
return;
}
Stat tmp = *this;
tmp.count = count + stat.count;
tmp.sum = sum + stat.sum;
tmp.minval = minval <= stat.minval ? minval : stat.minval;
tmp.maxval = maxval >= stat.maxval ? maxval : stat.maxval;
tmp.avg = tmp.sum / double(tmp.count);
tmp.varsum = varsum + stat.varsum;
tmp.var = tmp.varsum / double(tmp.count);
tmp.stddev = sqrt(tmp.var);
*this = tmp;
}
static NdbOut&
operator<<(NdbOut& out, const Stat& stat)
{
out << stat.name << ": " << "count: " << stat.count
<< " min: " << stat.minval << " max: " << stat.maxval
<< " avg: " << stat.avg << " stddev: " << stat.stddev;
return out;
}
template <class T, class V>
static void
computestat(Stat& stat)
{
stat.init();
stat.name = V::name();
const T* array = V::array();
stat.count = V::count();
assert(stat.count != 0);
uint i;
for (i = 0; i < stat.count; i++) {
const T& item = array[i];
double data = V::data(item);
stat.sum += data;
if (i == 0)
stat.minval = stat.maxval = data;
else {
if (stat.minval > data)
stat.minval = data;
if (stat.maxval < data)
stat.maxval = data;
}
}
stat.avg = stat.sum / double(stat.count);
stat.varsum = 0.0;
for (i = 0; i < stat.count; i++) {
const T& item = array[i];
double data = V::data(item);
double x = data - stat.avg;
stat.varsum += x * x;
}
stat.var = stat.varsum / double(stat.count);
stat.stddev = sqrt(stat.var);
}
struct V_rpk {
static const char* name() { return "rec per key"; }
static const Key* array() { return g_sortkeys; }
static uint count() { return g_sortcount; }
static double data(const Key& key) { return (double)key.rpk; }
};
struct V_rir {
static const char* name() { return "rir err pct"; }
static const Range* array() { return g_ranges; }
static uint count() { return g_opts.ops; }
static double data(const Range& range) { return (double)range.errpct; }
};
template static void computestat<Key, V_rpk>(Stat& stat);
template static void computestat<Range, V_rir>(Stat& stat);
static Stat g_stat_rpk; // summaries over loops
static Stat g_stat_rir;
static void
loopstats()
{
Stat stat_rpk; // records per key
Stat stat_rir; // record in range
if (g_loop == 0) {
g_stat_rpk.init();
g_stat_rir.init();
}
computestat<Key, V_rpk>(stat_rpk);
computestat<Range, V_rir>(stat_rir);
if (g_opts.loop != 1) {
ll0("=== loop " << g_loop << " summary ===");
ll0(stat_rpk);
ll0(stat_rir);
}
// accumulate
g_stat_rpk.add(stat_rpk);
g_stat_rir.add(stat_rir);
}
static void
finalstats()
{
ll0("=== summary ===");
ll0(g_stat_rpk);
ll0(g_stat_rir);
}
static void
setseed(int n)
{
uint seed;
if (n == -1) {
if (g_opts.seed == 0)
return;
if (g_opts.seed != -1)
seed = (uint)g_opts.seed;
else
seed = 1 + (ushort)getpid();
} else {
if (g_opts.seed != 0)
return;
seed = n;
}
ll0("seed=" << seed);
srandom(seed);
}
static int
runtest()
{
setseed(-1);
g_cs = get_charset_by_name(g_csname, MYF(0));
if (g_cs == 0)
g_cs = get_charset_by_csname(g_csname, MY_CS_PRIMARY, MYF(0));
chkrc(g_cs != 0);
for (g_loop = 0; g_opts.loop == 0 || g_loop < g_opts.loop; g_loop++) {
ll0("=== loop " << g_loop << " ===");
setseed(g_loop);
chkrc(createtable() == 0);
chkrc(loaddata() == 0);
sortkeys();
chkrc(allocranges() == 0);
makeranges();
chkrc(allocstat() == 0);
chkrc(runscans() == 0);
chkrc(droptable() == 0);
loopstats();
}
finalstats();
return 0;
}
NDB_STD_OPTS_VARS;
static struct my_option
my_long_options[] =
{
NDB_STD_OPTS("testIndexStat"),
{ "loglevel", 1001, "Logging level in this program 0-3 (default 0)",
(gptr*)&g_opts.loglevel, (gptr*)&g_opts.loglevel, 0,
GET_INT, REQUIRED_ARG, 0, 0, 0, 0, 0, 0 },
{ "seed", 1002, "Random seed (0=loop number, default -1=random)",
(gptr*)&g_opts.seed, (gptr*)&g_opts.seed, 0,
GET_INT, REQUIRED_ARG, -1, 0, 0, 0, 0, 0 },
{ "loop", 1003, "Number of test loops (default 1, 0=forever)",
(gptr*)&g_opts.loop, (gptr*)&g_opts.loop, 0,
GET_INT, REQUIRED_ARG, 1, 0, 0, 0, 0, 0 },
{ "rows", 1004, "Number of rows (default 100000)",
(gptr*)&g_opts.rows, (gptr*)&g_opts.rows, 0,
GET_UINT, REQUIRED_ARG, 100000, 0, 0, 0, 0, 0 },
{ "ops", 1005, "Number of index scans per loop (default 1000)",
(gptr*)&g_opts.ops, (gptr*)&g_opts.ops, 0,
GET_UINT, REQUIRED_ARG, 1000, 0, 0, 0, 0, 0 },
{ "dupkeys", 1006, "Pct records per key (min 100, default 1000)",
(gptr*)&g_opts.dupkeys, (gptr*)&g_opts.dupkeys, 0,
GET_UINT, REQUIRED_ARG, 1000, 0, 0, 0, 0, 0 },
{ "scanpct", 1007, "Preferred max pct of total rows per scan (default 5)",
(gptr*)&g_opts.scanpct, (gptr*)&g_opts.scanpct, 0,
GET_UINT, REQUIRED_ARG, 5, 0, 0, 0, 0, 0 },
{ "nullkeys", 1008, "Pct nulls in each key attribute (default 10)",
(gptr*)&g_opts.nullkeys, (gptr*)&g_opts.nullkeys, 0,
GET_UINT, REQUIRED_ARG, 10, 0, 0, 0, 0, 0 },
{ "eqscans", 1009, "Pct scans for partial/full equality (default 50)",
(gptr*)&g_opts.eqscans, (gptr*)&g_opts.eqscans, 0,
GET_UINT, REQUIRED_ARG, 50, 0, 0, 0, 0, 0 },
{ "dupscans", 1010, "Pct scans using same bounds (default 10)",
(gptr*)&g_opts.dupscans, (gptr*)&g_opts.dupscans, 0,
GET_UINT, REQUIRED_ARG, 10, 0, 0, 0, 0, 0 },
{ "keeptable", 1011, "Use existing table and data if any and do not drop",
(gptr*)&g_opts.keeptable, (gptr*)&g_opts.keeptable, 0,
GET_BOOL, NO_ARG, 0, 0, 0, 0, 0, 0 },
{ "no-extra-checks", 1012, "Omit expensive consistency checks",
(gptr*)&g_opts.nochecks, (gptr*)&g_opts.nochecks, 0,
GET_BOOL, NO_ARG, 0, 0, 0, 0, 0, 0 },
{ "abort-on-error", 1013, "Dump core on any error",
(gptr*)&g_opts.abort, (gptr*)&g_opts.abort, 0,
GET_BOOL, NO_ARG, 0, 0, 0, 0, 0, 0 },
{ 0, 0, 0,
0, 0, 0,
GET_NO_ARG, NO_ARG, 0, 0, 0, 0, 0, 0 }
};
static void
usage()
{
ndbout
<< g_progname
<< ": measure records_in_range error as percentage of total rows" << endl;
my_print_help(my_long_options);
}
static int
checkoptions()
{
chkrc(g_opts.rows != 0);
chkrc(g_opts.nullkeys <= 100);
chkrc(g_opts.dupkeys >= 100);
chkrc(g_opts.scanpct <= 100);
chkrc(g_opts.eqscans <= 100);
chkrc(g_opts.dupscans <= 100);
return 0;
}
static int
doconnect()
{
g_ncc = new Ndb_cluster_connection();
chkdb(g_ncc->connect(30) == 0);
g_ndb = new Ndb(g_ncc, "TEST_DB");
chkdb(g_ndb->init() == 0 && g_ndb->waitUntilReady(30) == 0);
return 0;
}
static void
freeall()
{
delete g_stat;
freekeys();
freeranges();
delete g_ndb;
delete g_ncc;
}
int
main(int argc, char** argv)
{
ndb_init();
const char* g_progname =
strchr(argv[0], '/') ? strrchr(argv[0], '/') + 1 : argv[0];
uint i;
ndbout << g_progname;
for (i = 1; i < argc; i++)
ndbout << " " << argv[i];
ndbout << endl;
int ret;
ret = handle_options(&argc, &argv, my_long_options, ndb_std_get_one_option);
if (ret != 0 || argc != 0)
return NDBT_ProgramExit(NDBT_WRONGARGS);
if (checkoptions() == 0 && doconnect() == 0 && runtest() == 0) {
freeall();
return NDBT_ProgramExit(NDBT_OK);
}
freeall();
return NDBT_ProgramExit(NDBT_FAILED);
}
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